Clean Room Rodless Cylinder Series CYP ø15, ø32 L1 M2 = m g (L1 + B) 103 2. Static moment m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 & M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103 m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We (L2 + A) 103 3.
(mm) a b Effective area (mm2) Weight (g) D L M2 Model 3.2 4 KJH02-23 KJH02-04 8.4 9.3 26.6 26.6 8.8 8.8 12.7 12.7 0.9 0.9 2.4 3.2 2 M1 M2 D D L Applicable tubing a Applicable tubing b Male elbow: KJL T H A Applicable tubing O.D.
Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 and M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We(L2 + A) 103 3.
Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 and M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We(L2 + A) 103 3.
L1 M2 = m g (L1 + B) 103 2. Static moment m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 & M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103 m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We (L2 + A) 103 3.
Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 and M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We(L2 + A) 103 3.
MHCM2-7S D8.3 205.2 2-M2 x 0.4 thread (Mounting thread) 2-M2 x 0.4 depth 4 (Mounting thread) 2.5 2 1.5 When open 20 When closed 7 10 6 4.5 15 11 7.7 1.8 16.5 6 100.05 (23) M3 x 0.5 (Finger closing port) 2-M2 x 0.4 thread (Attachment mounting thread) 4 0 0.03 3 12-8-23
Static moment M2 = WL1 = 100.05 = 0.5 [Nm] 2 = M2/M2max = 0.5/16 = 0.031 W = 1 [kg] =10 [N] Investigate M2. Since M1 & M3 are not generated, investigation is unnecessary. Find the value of M2max when Va = 300mm/s from
MHCM2-7S D8.3 205.2 2-M2 x 0.4 thread (Mounting thread) 2-M2 x 0.4 depth 4 (Mounting thread) 2.5 2 1.5 When open 20 When closed 7 10 6 4.5 15 11 7.7 1.8 16.5 6 100.05 (23) M3 x 0.5 (Finger closing port) 2-M2 x 0.4 thread (Attachment mounting thread) 4 0 0.03 3 12-8-23
Max. system pressure (MPa) Av x 10-6 m2 Cv converted Max. operating pressure differential (MPa) Weight (g) Max. operating pressure differential (MPa) Max. system pressure (MPa) Flow characteristics Flow characteristics Orifice size (mm) Model AC Orifice size (mm) Model AC Note) Note) Port size Port size Weight (g) Av x 10-6 m2 Cv converted VXK2112-01 VXK2122-01 VXK2132-01 VXK2112-02 VXK2122
Cylinder Allowable Static Moment: Common to M1, M2, and M3 (Nm) Moment Center Distance (mm) Bore (mm) Stroke(mm) 10 20 30 40 50 75 100 125 150 Cp Cy Cr MXS6 0.70 0.98 1.22 1.22 1.22 11 13 16 MXS8 2.06 2.06 2.78 3.59 4.17 4.17 11 13 20 MXS12 4.26 4.26 4.26 5.81 7.11 9.95 9.95 24 26 25 MXS16 8.33 8.33 8.33 8.33 11.42 17.13 22.84 22.84 27 30 31 MXS20 13.79 13.79 13.79 13.79 19.31 24.83 35.87
SV1000-67-1A S0700 SV2000-67-1A M2: 0.16 Nm M3: 0.8 Nm M4: 1.4 Nm SV3000-67-1A VQ SV4000-67-1A VQ4 Silencer with One-touch fitting This silencer can be quickly mounted on the manifolds E (exhaust) port.
Value is different from Kv and Cv factors for pneumatic purpose due to different test method. 3 3 Water flow rate Q0 [L/min] (When Av = 1 x 106 [m2]) Saturated steam flow rate Q0 [kg/h] (when Av = 1 x 106 [m2]) 2 Upstream pressure P1 = 1 MPa 2 P1 = 0.8 MPa 1 0.9 0.8 0.7 0.6 1 0.9 0.8 0.7 0.6 P1 = 0.6 MPa Example 2 P1 = 0.5 MPa P1 = 0.4 MPa 0.5 0.5 0.4 0.4 Example 1 P1 = 0.3 MPa 0.3 0.3 P1
= d x e x f x Relative density m2 = 4 x 5 + 6 x 2.7 x 10-6 = 3.24 x 10-4 (kg) Inertial moment around Z2 axis IZ2 = {m2 (d2 x e2) / 12} x 10-6 IZ2 = {3.24 x 10-4 x (42 + 52) / 12} x 10-6 = 1.11 x 10-9 (kg.m2) = 1.11 x 10-9 + 3.24 x 10-4 x 23.52 x 10-6 = 0.18 x 10-6 (kg.m2) Inertial moment around Z axis IB = IZ2 x m2r22 x 10-6 IB Thus, the total inertial moment is I = IA x B I = 0.20 x 10
Dimensions Vacuum suction 2-M2 x 3 (Counter sunk Phillips screw for precision equipment) 2-M2 x 3 (Round head Phillips screw for precision equipment ) Relief port Cover installed in end cap section Vacuum suction Relief port 11-MXP 2-M3 x 8 (hexagon socket head screw) 2-M2 x 5 (hexagon socket head screw) MXP10, 12, 16 MXP6 Note Applicable size Switch rail model MXP 65 MXP-AD 65 MXP 6-10 MXP10
Static moment M2 = WL1 = 100.2 = 2 [Nm] 2 = M2/M2 max = 2/16 = 0.125 W = 1 [kg] = 10 [N] W Review M2. Since M1 & M3 are not generated, review is unnecessary. M L1 3. Dynamic moment We = 5 x 10-3WgU = 5 x 10-31.9.8500 = 25 [N ] Me3 = 1/3We(L2-A) = 1/3250.182 = 1.52 [Nm] 3 = Me3/Me3max = 1.52/6 = 0.25 Me3 Review Me3. (For Memax, find the value in
Dimensions 2-M2 x 3 (Countersunk head Phillips screw for precision instruments) 2-M2 x 3 (Cross recessed head machine screw for precision instruments) 2-M3 x 8 (Bolt with hex. hole) 2-M2 x 5 (Bolt with hex. hole) MXP10/12/16 MXP6 Applicable size Switch rail part no.
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, VACUUM EJECTOR, COMPACT, VACUUM SERIES, ZA COMPACT VACUUM EJECTOR, AG, ZA NOZZLE SIZE 0.5, .00000 lb
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, VACUUM EJECTOR, COMPACT, VACUUM SERIES, ZA COMPACT VACUUM EJECTOR, AG, ZA NOZZLE SIZE 0.5, 2.64554 lb
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, VACUUM EJECTOR, COMPACT, VACUUM SERIES, ZA COMPACT VACUUM EJECTOR, AG, ZA NOZZLE SIZE 0.5, 2.64554 lb